Enhancing Quantum Information Distribution Through Noisy Channels Using Quantum Communication Architectures

Enhancing Quantum Information Distribution Through Noisy Channels Using Quantum Communication Architectures

Quantum information transmission is subject to imperfections in communication processes and systems. These phenomena alter the original content due to decoherence and noise. However, suitable communication architectures incorporating quantum and classical redundancy can selectively remove these erro...

Full description

Saved in:
Bibliographic Details
Main Author: Francisco Delgado
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Information
Subjects:
communication architectures
Pauli channels
quantum error mitigation
quantum error correction
path superposition
indefinite causal order
Online Access:https://www.mdpi.com/2078-2489/16/6/485
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Quantum information transmission is subject to imperfections in communication processes and systems. These phenomena alter the original content due to decoherence and noise. However, suitable communication architectures incorporating quantum and classical redundancy can selectively remove these errors, boosting destructive interference. In this work, a selection of architectures based on path superposition or indefinite causal order were analyzed under appropriate configurations, alongside traditional methods such as classical redundancy, thus enhancing transmission. For that purpose, we examined a broad family of decoherent channels associated with the qubit chain transmission by passing through tailored arrangements or composite architectures of imperfect channels. The outcomes demonstrated that, when combined with traditional redundancy, these configurations could significantly improve the transmission across a substantial subset of the channels. For quantum key distribution purposes, two alternative bases were considered to encode the information chain. Because a control system must be introduced in the proposed architectures, two strategies for its disposal at the end of the communication process were compared: tracing and measurement. In addition, eavesdropping was also explored under a representative scenario, to quantify its impact on the most promising architecture analyzed. Thus, in terms of transmission quality and security, the analysis revealed significant advantages over direct transmission schemes.
ISSN:2078-2489

Similar Items